Key stabilizing elements of protein structure identified through pressure and temperature perturbation of its hydrogen bond network.

Hydrogen bonds are key constituents of biomolecular structures, and their response to external perturbations may reveal important insights about the most stable components of a structure. NMR spectroscopy can probe hydrogen bond deformations at very high resolution through hydrogen bond scalar couplings (HBCs). However, the small size of HBCs has so far prevented a comprehensive quantitative characterization of protein hydrogen bonds as a function of the basic thermodynamic parameters of pressure and temperature. Using a newly developed pressure cell, we have now mapped pressure- and temperature-dependent changes of 31 hydrogen bonds in ubiquitin by measuring HBCs with very high precision. Short-range hydrogen bonds are only moderately perturbed, but many hydrogen bonds with large sequence separations (high contact order) show greater changes. In contrast, other high-contact-order hydrogen bonds remain virtually unaffected. The specific stabilization of such topologically important connections may present a general principle with which to achieve protein stability and to preserve structural integrity during protein function.

[1]  R. Brüschweiler,et al.  QUANTUM-CHEMICAL CHARACTERIZATION OF NUCLEAR SPIN-SPIN COUPLINGS ACROSS HYDROGEN BONDS , 1999 .

[2]  Ryan Day,et al.  Water penetration in the low and high pressure native states of ubiquitin , 2008, Proteins.

[3]  G. Reinhart,et al.  Baroresistant buffer mixtures for biochemical analyses. , 2005, Analytical biochemistry.

[4]  P. Wright,et al.  High pressure NMR reveals that apomyoglobin is an equilibrium mixture from the native to the unfolded. , 2002, Journal of molecular biology.

[5]  G. Rose,et al.  Are proteins made from a limited parts list? , 2005, Trends in biochemical sciences.

[6]  Tan Inoue,et al.  Minimal catalytic domain of a group I self-splicing intron RNA , 2000, Nature Structural Biology.

[7]  C. Tanford Contribution of Hydrophobic Interactions to the Stability of the Globular Conformation of Proteins , 1962 .

[8]  Kazuyuki Akasaka,et al.  Close identity of a pressure-stabilized intermediate with a kinetic intermediate in protein folding , 2003, Proceedings of the National Academy of Sciences of the United States of America.

[9]  C. Bugg,et al.  Structure of ubiquitin refined at 1.8 A resolution. , 1987, Journal of molecular biology.

[10]  S. Grzesiek,et al.  Direct Observation of Hydrogen Bonds in Nucleic Acid Base Pairs by Internucleotide 2JNN Couplings , 1998 .

[11]  A. Gronenborn,et al.  Pressure alters electronic orbital overlap in hydrogen bonds , 2000, Journal of biomolecular NMR.

[12]  S. Grzesiek,et al.  Temperature-dependence of protein hydrogen bond properties as studied by high-resolution NMR. , 2002, Journal of molecular biology.

[13]  S. Khorasanizadeh,et al.  Evidence for a three-state model of protein folding from kinetic analysis of ubiquitin variants with altered core residues , 1996, Nature Structural Biology.

[14]  J. Bell,et al.  Experiment and Theory , 1968 .

[15]  David J Wilton,et al.  Pressure‐induced changes in the solution structure of the GB1 domain of protein G , 2007, Proteins.

[16]  M. Barfield,et al.  Structural dependencies of interresidue scalar coupling (h3)J(NC') and donor (1)H chemical shifts in the hydrogen bonding regions of proteins. , 2002, Journal of the American Chemical Society.

[17]  S. Grzesiek,et al.  Insights into biomolecular hydrogen bonds from hydrogen bond scalar couplings , 2004 .

[18]  S. Hawley,et al.  Reversible pressure--temperature denaturation of chymotrypsinogen. , 1971, Biochemistry.

[19]  W. M. Westler,et al.  Trans-hydrogen-bond (h2)J(NN) and (h1)J(NH) couplings in the DNA A-T base pair: natural bond orbital analysis. , 2002, Journal of the American Chemical Society.

[20]  S. Grzesiek,et al.  Correlation of protein structure and dynamics to scalar couplings across hydrogen bonds. , 2007, Journal of the American Chemical Society.

[21]  P. Privalov,et al.  Cold denaturation of myoglobin. , 1986, Journal of molecular biology.

[22]  G. Makhatadze,et al.  Anion binding to the ubiquitin molecule , 1998, Protein science : a publication of the Protein Society.

[23]  H. Scheraga,et al.  Contribution of unusual Arginine-Arginine short-range interactions to stabilization and recognition in proteins , 1994, Journal of protein chemistry.

[24]  A. Wand,et al.  Direct access to the cooperative substructure of proteins and the protein ensemble via cold denaturation , 2004, Nature Structural &Molecular Biology.

[25]  J. R. Grigera,et al.  The behavior of the hydrophobic effect under pressure and protein denaturation. , 2010, Biophysical journal.

[26]  L. Smeller Pressure-temperature phase diagrams of biomolecules. , 2002, Biochimica et biophysica acta.

[27]  G. Desiraju A bond by any other name. , 2011, Angewandte Chemie.

[28]  Frank Weinhold,et al.  Natural bond orbital analysis of steric interactions , 1997 .

[29]  O. Malkina,et al.  Nuclear magnetic resonance of hydrogen bonded clusters between F− and (HF)n: Experiment and theory , 1998 .

[30]  S. Grzesiek,et al.  Observation of the closing of individual hydrogen bonds during TFE–induced helix formation in a peptide , 2001, Protein science : a publication of the Protein Society.

[31]  Oliver F. Lange,et al.  NMR Structure Determination for Larger Proteins Using Backbone-Only Data , 2010, Science.

[32]  Ad Bax,et al.  Validation of Protein Structure from Anisotropic Carbonyl Chemical Shifts in a Dilute Liquid Crystalline Phase , 1998 .

[33]  Walter Kauzmann,et al.  Thermodynamics of unfolding , 1987, Nature.

[34]  H. Kalbitzer,et al.  Pressure-induced local unfolding of the Ras binding domain of RalGDS , 2000, Nature Structural Biology.

[35]  S. Grzesiek,et al.  NMRPipe: A multidimensional spectral processing system based on UNIX pipes , 1995, Journal of biomolecular NMR.

[36]  H. Kalbitzer,et al.  15N and 1H NMR study of histidine containing protein (hpr) from staphylococcus carnosus at high pressure , 2008, Protein science : a publication of the Protein Society.

[37]  Shigeyuki Yokoyama,et al.  NMR snapshots of a fluctuating protein structure: ubiquitin at 30 bar-3 kbar. , 2005, Journal of molecular biology.

[38]  T. Sosnick,et al.  Protein folding intermediates: native-state hydrogen exchange. , 1995, Science.

[39]  Christina Kiel,et al.  The ubiquitin domain superfold: structure-based sequence alignments and characterization of binding epitopes. , 2006, Journal of molecular biology.

[40]  Oliver F. Lange,et al.  Recognition Dynamics Up to Microseconds Revealed from an RDC-Derived Ubiquitin Ensemble in Solution , 2008, Science.

[41]  W. Kauzmann Some factors in the interpretation of protein denaturation. , 1959, Advances in protein chemistry.

[42]  A. Gronenborn,et al.  Correlation between 3hJNC‘ and Hydrogen Bond Length in Proteins , 1999 .

[43]  Robert Powers,et al.  A common sense approach to peak picking in two-, three-, and four-dimensional spectra using automatic computer analysis of contour diagrams , 1991 .

[44]  R. L. Baldwin,et al.  Temperature dependence of the hydrophobic interaction in protein folding. , 1986, Proceedings of the National Academy of Sciences of the United States of America.

[45]  S. Grzesiek,et al.  Direct detection of N−H⋯O=C hydrogen bonds in biomolecules by NMR spectroscopy , 2008, Nature Protocols.

[46]  Linda Hicke,et al.  Ubiquitin-binding domains , 2005, Nature Reviews Molecular Cell Biology.

[47]  R. Brüschweiler,et al.  Variation in quadrupole couplings of alpha deuterons in ubiquitin suggests the presence of C(alpha)-H(alpha)...O=C hydrogen bonds. , 2010, Journal of the American Chemical Society.

[48]  D. S. Garrett,et al.  A common sense approach to peak picking in two-, three-, and four-dimensional spectra using automatic computer analysis of contour diagrams. 1991. , 2011, Journal of magnetic resonance.

[49]  A. Bax,et al.  Identification of the Hydrogen Bonding Network in a Protein by Scalar Couplings , 1999 .

[50]  G. Hummer,et al.  The pressure dependence of hydrophobic interactions is consistent with the observed pressure denaturation of proteins. , 1998, Proceedings of the National Academy of Sciences of the United States of America.

[51]  S. Grzesiek,et al.  Direct Observation of Hydrogen Bonds in Proteins by Interresidue 3hJNC' Scalar Couplings , 1999 .

[52]  R. Winter,et al.  Temperature- and pressure-induced unfolding and refolding of ubiquitin: a static and kinetic Fourier transform infrared spectroscopy study. , 2002, Biochemistry.